The invention relates to a paper cup with a cup sleeve and a bottom connected in a liquid-tight manner to the cup sleeve.
Known paper cups are made from paper segments wound using a folding mandrel into a frustum shape. By shaping of a top curl on the top edge of the frustum-shaped cup sleeve and by inserting a bottom into the cup sleeve, a paper cup for receiving liquids is provided. If hot beverages are to be received, the paper cup can be additionally provided with an insulating outer envelope. During shaping of the top curl and also during connection of the bottom to the cup sleeve at an all-round bottom edge, the paper material of the cup sleeve must be curled or folded round by at least 180°. To do so, the paper material must be compressed in the area of the bottom edge, and partly stretched and partly compressed in the area of the top curl. Compressing leads to an excess of paper material and hence to a more or less rippled surface. This can be accepted on an inside of the bottom edge, but a rippled surface cannot be accepted at the top curl. As a result, numerous measures must be taken in the area of the top curl in order to make a top curl with a smooth surface. The compressing or stretching of the paper material during curling or folding round is all the greater as the cone angle of the cup sleeve increases. Using the example of the top curl, the upper rim of the cup sleeve in the case of a cylindrical tube is stretched during curling, as soon as it has been curled by 360° and hence substantially is back in its initial position, but there is no substantial material stretching or material compression. This is not the case with frustum-shaped sleeves, since the upper rim of the cup sleeve is moved during provision of the top curl into a position in which a smaller diameter is obtained in comparison with the original diameter of the upper rim. After a curling process of the upper rim by 360° too, the paper material of the upper rim must therefore be able to sustain a permanent material compression without creasing. The greater the cone angle of the cup sleeve, the greater this diameter difference is and the greater is the tendency during creation of the top curl and during creation of the bottom edge to crease. For this reason, conventional paper cups are made with a cone angle of the cup sleeve of 9° at most.
The invention is intended to provide a paper cup which is suitable not only for receiving liquids, but also for receiving and for consumption of foods, for example soups.
In accordance with the invention, a paper cup with a cup sleeve and a bottom connected to the cup sleeve in a liquid-tight manner is provided, in which the cup sleeve is arranged between the bottom and an end opposite the bottom at least in some sections at an angle greater than or equal to 10°, in particular between 10° and 15° or between 10° and 25°, relative to a central longitudinal axis of the paper cup.
By providing a larger cone angle of the cup sleeve, a bowl-like paper cup is obtained that is well suited in particular for receiving soups or other food. The substantial feature here is the flatter side wall of the paper cup in accordance with the invention when compared with conventional paper cups, considerably facilitating the consumption of food out of the paper cup. Not least, it is possible thanks to the wider opening angle of the paper cup to provide a comparatively wide cup opening without the capacity of the paper cup becoming excessively large. This too facilitates the consumption of food directly from the paper cup in accordance with the invention, since for example the cup opening is large enough to move a spoon inside the cup's volume.
In an embodiment of the invention, the cup sleeve is connected in liquid-tight manner by an all-round edge to the bottom, where the edge is arranged parallel to a central longitudinal axis or is designed flaring from the bottom to the end of the edge.
With an embodiment of this type for a bottom edge, firstly an attractive bowl-like appearance of the paper cup in accordance with the invention is achieved, since the cylindrical or inverse-conical design of the edge has the optical effect of a kind of base, and furthermore the standing surface is enlarged compared with a strictly frustum shaped design of the paper cup.
In an embodiment of the invention, a top curl is shaped on an upper rim, opposite the bottom, of the cup sleeve.
A cup with top curl can be brought up to the mouth without problems and is pleasant to use. Furthermore, the upper rim of the cup sleeve is substantially stabilized by the top curl. This is of particular importance for paper cups with large diameter.
In an embodiment of the invention, the cup sleeve is, between the bottom and an end opposite the bottom, curved outwards at least in some sections when viewed from the interior of the cup.
In this way the cup is provided with a very attractive and bowl-like shape. Furthermore, it is possible thanks to the outward-curving cup sleeve to obtain a cup shape very well suited for eating using a spoon, for example.
In an embodiment of the invention, the cup sleeve is, between the bottom and an end opposite the bottom, curved inwards at least in some sections when viewed from the interior of the cup.
With this concave design of the cup sleeve, a shape very easily gripped and held by the human hand is obtained despite its wide opening. Furthermore, the volume of such a paper cup with concave cup sleeve can be kept small despite the wide opening.
In an embodiment of the invention, a wall of the cup sleeve is designed with S-shaped cross-section, so that the cup sleeve is, in the area of the bottom and in the area of its end opposite the bottom, at a lower angle relative to the central longitudinal axis than in a central section.
Thanks to an S-shaped design like this of the cup sleeve, shaping of a top curl and of a bottom edge is considerably facilitated, because despite the angle greater than or equal to 10° in a central section of the cup sleeve, an angle of less than 10°, for example, applies in the area of the bottom and in the area of the upper rim, and in any event a lower angle than in the middle, so that a top curl and an edge can be shaped without any problem and without having to fear any excessive rippling or tearing of the paper material. Nevertheless, the bowl-like impression of the paper cup is retained.
In an embodiment of the invention, the cup sleeve is connected in liquid-tight manner to the bottom by means of an all-round edge, where the edge is formed by folding a lower rim area of the cup sleeve around a bottom rim, or a lower rim area of the bottom around the lower rim of the cup sleeve, where the lower rim area of the cup sleeve or the lower rim area of the bottom is provided with notches out of the paper material.
Thanks to notches out of the paper material, the upper and lower rim of the cup sleeve can be shaped substantially more easily and in particular tearing of the paper material or excessive rippling are avoided.
In an embodiment of the invention, the notches extend from the rim of the bottom or from the rim of the cup sleeve to no more than half the height of the edge.
In this way, the shaping of the bottom edge can be substantially facilitated without its dependably liquid-tight design being endangered, because up to half the height of the edge the folded-over paper material is in full-surface contact with the rim of the bottom or with the rim of the cup sleeve, so that an all-round and continuous seal can be achieved.
In an embodiment of the invention, the cup sleeve is provided with an all-round recess projecting into the interior of the cup, and a lower rim of the edge is dimensioned such that an outer circumference of the lower rim of the edge is smaller than or equal in size to a larger diameter at the recess and larger than a smaller diameter at the recess.
With a design of this type for the edge and for the recess, the edge can rest on the recess when several cups are stacked. Several cups can be stacked as a result without the bottom edge of the top cup sticking in the lower cup. Thanks to the wide angle that the cup sleeve takes at least in some sections relative to the central longitudinal axis, the cup sleeves of several stacked cups are then no longer in contact with one another, so that no sticking need be feared even when numerous paper cups are stacked.
In an embodiment of the invention, the cup is designed at least in some sections with double walls.
In this way, an insulating cup can be provided in which even very hot foods such as noodle soup can be received without problem and nevertheless held without any risk to the hand of the user.
The problem underlying the present invention is also solved by a method for making a paper cup with a cup sleeve and a bottom, where the cup sleeve has a top curl shaped at an end of the cup sleeve opposite the bottom, where the cup sleeve is arranged between the bottom and an end opposite the bottom at least in some sections at an angle greater than or equal to 10°, in particular between 10° and 15°, relative to a central longitudinal axis of the paper cup.
In an embodiment of the invention, the top curl is formed in at least two curling steps, where the cup sleeve is clamped in different ways during the curling steps at least partially by holding devices.
Surprisingly, it has proved that despite the wide angle greater than or equal to 10° which the cup sleeve takes at least in some sections relative to the central longitudinal axis, the shaping of a top curl is possible by splitting the forming of the top curl into at least two curling steps and in addition clamping the cup sleeve in different ways during the different curling steps. The aim is to prevent the buckling of the cup wall during the curling steps such that the cup sleeve is clamped during the different curling steps in each case just below the upper rim of the cup sleeve or the already partially completed top curl. Thanks to this repeated clamping, the top curl can be dependably shaped without any fear of bulging or buckling of the cup sleeve.
In an embodiment of the invention, four curling steps are provided for shaping the top curl. Advantageously a curl of at most 180° is provided in each curling step. It can also be provided that in a first curling step a curl of 180° and in subsequent curling steps a curl of about 90° is provided. A split of this type into four curling steps and into a first curl of about 180° and subsequent curls of about 90° permits process-reliable shaping of a top curl even with very wide angles between the central longitudinal axis and the cup sleeve of more than 10° and even up to an angle of 15°.
In an embodiment of the invention, the steps provided are picking up the cup sleeve in a holding ring, moving a holding punch into the cup sleeve, clamping the cup sleeve between the holding ring and the holding punch, and applying a curling tool to the upper rim of the cup sleeve.
At least partly differing curling tools and at least partly differing holding tools can be used here. The use of one and the same holding ring, but differing holding punches and curling tools, is advantageous. If necessary the formed top curl can be pressed flat too in order to provide a sealing surface for attachment of a diaphragm closing the cup.
The problem underlying the invention is also solved by a device for making a paper cup with a cup sleeve and a bottom where the cup sleeve has a top curl shaped on an end of the cup sleeve opposite the bottom, where means for arranging the cup sleeve between the bottom and an end opposite the bottom are provided at least in some sections at an angle greater than or equal to 10°, in particular between 10° and 15°, relative to a central longitudinal axis of the paper cup.
In an embodiment of the invention, means are provided for infeed of at least one curling tool for forming of the top curl at least in some sections on the upper rim of the cup sleeve, where an infeed direction is approximately parallel to a section of the upper rim area of the cup sleeve to be processed by the curling tool.
Since an infeed direction of the curling tool is approximately parallel to the material of the cup sleeve, buckling or bulging of the cup sleeve during forming of the top curl can be avoided, since the paper material is very stable against a thrust load approximately parallel to the material of the cup sleeve, so that even high pressure forces can be applied to the sleeve during forming of the top curl.
In an embodiment of the invention, the curling tool is split over the upper circumference of the cup sleeve into several segments which are each arranged movably parallel to a section of the upper rim area of the cup sleeve to be processed by the respective segment.
By means of this splitting of the curling tool into several segments, the achievable result is a variable diameter of the curling tool during infeed. This is particularly useful in particular for wide angles of the cup sleeve of more than 10° relative to the central longitudinal axis, in order to ensure an infeed direction of the curling tool that is approximately parallel to the material of the cup sleeve.
Further features and advantages of the invention can be found in the claims and the following description of preferred embodiments of the invention in conjunction with the drawings. Individual features of the various embodiments can here be combined with one another as required without going beyond the scope of the invention.
The view of
The illustration in
A cone angle of the cup sleeves 12, 22 is greater than or equal to 10°, for example 11° in the paper cup 10 or 15° in the paper cup 20, and ensures a bowl-like appearance of the paper cups 10, 20 and also that a comparatively wide opening surrounded by the respective top curls 14 of the paper cups 10, 20 can nevertheless be provided with a low volume. In addition, the comparative obliquely running inner wall of the cup sleeve contributes to allowing food to be eaten from the paper cups 10, 20 using a spoon without problems. The wide opening and the wide angle α, β between the cup wall and the central longitudinal axis 16 facilitates the eating of food from the paper cups 12, 20 using a spoon. The paper cups 10, 20 are therefore especially suitable for food, for example liquid food such as noodle soup or the like.
The illustration in
The illustration in
The illustration in
Besides a visually very attractive bowl form of the paper cup 32, it is achieved by this S-shape of the cup sleeve that in those areas in which the top curl 36 or the bottom edge 40 are shaped an angle taken by the cup sleeve 34 relative to the central longitudinal axis 16 is smaller than in the middle area 38. As a result, the shaping of the top curl and the shaping of the bottom edge 40 are considerably facilitated, since with an increasing angle of the cup sleeve 34 relative to the central longitudinal axis 16 the paper material of the cup sleeve 34 must be more severely stretched or compressed and hence the danger of tearing or rippling increases. Thanks to the S-shape of the cup sleeve 34 of the paper cup 32, the visual impression of a bowl-like cup with a flat cup wall is achieved as a result, and nevertheless both the top curl 36 and the bottom 40 can be shaped without fear of increased rippling or even tearing of the paper material.
The illustration of
As shown in
Even numerous stacked cups 42 can therefore be separated again without problems.
As can be seen in the illustration in
The illustration in
In the illustration in
The illustration in
The illustration in
It can be discerned from
It can however also be discerned that the triangular notches 70 extend only to half the height of the bottom edge. Below the notches 70, therefore, a sufficiently large material section is available for all-round and complete sealing between the cup sleeve 66 and the bottom 72 to ensure a dependably liquid-tight connection of the bottom 72 to the cup sleeve 66.
The illustrations in
A first curling step of the upper rim 84 is shown in
The illustration in
The illustration in
The upper rim 84 of the paper cup 74 is folded around a further 90° by means of the third curling step shown in
The illustration in
After completion of the fourth curling step, the top curl 96 is completed on the paper cup 74.
The illustration in
Thanks to splitting up, in accordance with the invention, the forming of the top curl into several steps, for example four steps, in conjunction with a clamping of the upper area of the cup 74 as close as possible to the upper rim, it is possible despite the wide inclination angle of the cup wall to shape a top curl. Bulging or buckling of the upper cup area is here prevented by the variable clamping of the cup 74, matched to the respective curling tool, and the splitting up into individual curling steps, at least partly using different curling tools.
The illustration in
The illustration in
The curling tool 120 thus has, thanks to being split into individual segments 122, 124, a variable diameter of the curling groove. After complete infeed of the segments 122, 124 of the curling tool 129, the segments 122, 124 can be in contact by their side walls and form a closed and full circle of the curling groove. The crucial factor is that infeed of the individual segments 122, 124 takes place approximately parallel to the inclination angle of the upper rim of the paper cup 114, as then the upper rim of the paper cup 114 can project further beyond the holding punch 116 and the holding ring 118 than would be permissible in the case of non-parallel infeed of the curling tool to the upper rim. This is because with a non-parallel infeed of the curling tool, the tendency of the upper area of the paper cup 114 to buckle or bulge during application of the curling tool would be substantially greater than with the parallel infeed of the curling tool 120 shown by the arrow 126 as illustrated in
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